C&D Technologies RS-1476 Standby Battery Vented Cell User Manual

Lower than normal temperatures have the opposite effects. In general, at

recommended float voltage, a battery in a cool location will last longer and require

less maintenance than one in a warm location. If the operating temperature

is something other than 77°F (25°C), it is desirable to modify the float voltage

(temperature compensate) as follows:
For electrolyte temperatures other than 77°F (25°C), correct individual cell float

voltage by 2.8 mV/°F (5.0 mV/°C):
• Add 2.8 mV (0.0028 Volt) per °F (5.0 mV/°C) below 77°F (25°C)
• Subtract 2.8 mV (0.0028 Volts) per °F (5.0 mV/°C) above 77°F (25°C)
Example:

LCT 1680

Nominal float @ 77°F is 2.20 Vpc

Corrected float @ 67°F is 2.228 Vpc

Corrected float @ 87°F is 2.172 Vpc

At higher than normal operating temperatures, for every additional 15°F (8°C)

battery life is decreased by 50 percent. Therefore, continued operation at an

average cell temperature of 92°F (33°C) will reduce battery life to 50 percent of

that typical at 77°F (25°C). See Figure 4.1.4
At lower than normal operating temperatures, battery performance will be reduced

as shown in Figure 4.1.3.

Electrolyte level
When water is lost from the electrolyte the result will be a more

concentrated solution and thereby a higher specific gravity reading.

The reverse condition applies when water has been added to adjust

electrolyte level. The apparent level can be significantly effected by

charging voltage. If the voltage is higher than specified in the float

tables or if the battery is being charged at equalize voltage, gases

will be generated displacing the electrolyte causing the level to rise.

CAUTION

Never allow electrolyte level to drop below the bottom of the flame arrestor vent tube. Should this

occur, hydrogen generated within the cell will not be contained by the flame arrestor and ignition due

to external source is possible from an outside spark or flame.

Recharge and Electrolyte Stratification
When the battery is discharged, the specific gravity of its electrolyte is reduced. This is a result of the utilization of sulfate

ions in the chemical reaction with the active materials in the positive and negative plates. The sponge lead in the negative

plate and the lead dioxide in the positive plate convert to lead sulfate, combining the sulfate ions of the electrolyte with

the lead compounds in the plates.
On recharge, lead sulfate in the plates is converted back to the original compounds and the sulfate ions are released

from the plates. The sulfate ions combine to produce sulfuric acid with a density greater than that of the electrolyte.

As a result, the newly generated, concentrated (heavy acid) falls to the bottom of the cell container. Specific gravity

measurements taken at the top of the cell will be lower than those taken at the bottom. This physical condition is called

electrolyte stratification.
Stratification does not materially inhibit the ability of a lead acid battery to deliver power. However, battery performance

will be less than optimum and specific gravity measurements must take into consideration the non-homogeneity of the

electrolyte. Specific gravity measurements may not reflect the average cell gravity.
There are two ways to eliminate stratification. The first is to provide sufficient time for chemical diffusion. This can take

several weeks or longer at float potential, depending upon the degree of stratification.
A more efficient method is to provide an equalize charge voltage that will mix the electrolyte. Gases produced by an

equalizing charge stir up the electrolyte, causing uniformity throughout the cell. After a relatively short time, the electrolyte

will become mixed and homogenous. The degree of gassing and, hence the setting for the equalize potential are directly

associated with the time required for mixing.

FIGURE 4.1.3 - Battery capacity versus operating

temperature. See Appendix D for full chart

PART 4

REFERENCE INFORMATION, TROUBLE SHOOTING & EXTENDED MAINTENANCE (CONTINUED)

RS1476/0215/CD

22

www.cdtechno.com

FIGURE 4.1.4

Battery Life versus ambient temperature

See Appendix D for full chart